Contents

The final design for the bridge was approved in January 1952 by the New York State Department of Transportation, (previously named The New York State Department of Public Works). The design described a 155 meters (509 ft) crossing consisting of five simply supported spans with nominal lengths of 30.5 meters (100 ft), 33.5 m (110 ft), 36.6 m (120 ft), 33.5 m (110 ft), and 30.5 m (100 ft). The bridge was supported with pier frames along with abutments at each end. The pier frames were constructed of two slightly tapered columns with tie beams. The columns were fixed in place within a lightly reinforced plinth positioned on a shallow, reinforced spread footing. The spread footing was to be protected with a dry layer of riprap.[2]

The superstructure consisted of two longitudinal main girders with transverse floor beams. The skeleton of the bridge deck (200 millimeters (7.9 in) thick) was made up of steel stringers.

The bridge was partially opened during the summer of 1954 before construction was fully completed

The Schoharie Creek Bridge (NY 1020940, New York State bridge identification number), began full service beginning in October 1954.

In the spring and summer of 1955, the pier plinths began to show vertical cracks ranging from 3 to 5 mm (0.12 to 0.20 in), as a result of high tensile stresses in the concrete plinth. In 1957, plinth reinforcement was added to each of the four piers.

Almost a year later on October 16, 1955, the bridge was damaged by a flood.

On the morning of April 5, 1987, during the spring flood, the Schoharie Creek Bridge collapsed. A snowmelt combined with rainfall totaling 150 mm (5.9 in) produced an estimated 50 year flood.

Pier three was the first to collapse, which caused the progressive collapse of spans three and four. Ninety minutes later pier two and span two collapsed. Two hours later pier one and span one shifted. A National Transportation Safety Board investigation suggested that pier two collapsed because the wreckage of pier three and the two spans may have partially blocked the river, redirecting and increasing the velocity of the flow of water to pier two.

Six days later, 5 km (3.1 mi) upstream, a large section of the Mill Point Bridge collapsed. The bridge had been closed since the flood as a precaution that its foundations had also been eroded.[3]

At the time of the collapse, one car and one tractor-semitrailer were on the bridge. Before the road could be blocked off, three more cars drove into the gap. During the following three weeks, nine bodies were recovered from the river. The body of the 10th victim was recovered in the Mohawk River in July 1989.

It was concluded that the bridge collapsed due to extensive scour under pier three. The foundation of the pier was bearing on erodible soil, consisting of layers of gravel, sand and silt, inter-bedded with folded and tilted till. This allowed high velocity flood waters to penetrate the bearing stratum.

The area left around the footing was not filled with riprap stone, but instead was back-filled with erodible soil and topped off with dry riprap. Riprap protection, inspection, and maintenance were determined to have been inadequate.

The investigations showed that the scouring process under the piers began shortly after the bridge was built. At the time of the collapse, the upstream end of pier 3 fell into a scour hole approximately 3 meters (9.8 ft) deep. Investigators estimated that about 7.5 to 9 meters (25 to 30 ft) of the pier was undermined.

The design for the Schoharie Creek Bridge originally called for leaving sheet piles in place (which are used to keep water out of excavation areas during construction). The riprap would then have filled the area left between the pier footings and the sheeting. However, this sheeting was not left in place.

Another reason for the collapse was the weight of the riprap. The design specification called for riprap with 50 percent of the stones heavier than 1.3 kilonewtons (290 lbf), and the remainder between 0.44 and 1.3 kN (99 and 292 lbf). Investigators found that heavier riprap weights of 4.4 to 6.7 kN (990 to 1,510 lbf) should have been specified.

Other considerations as to the cause of the collapse included design of the superstructure, quality of materials and construction, inspection and maintenance. Investigations found that these factors did not contribute to the collapse.[4]

Twelve hours before the Schoharie Creek Bridge collapsed, due to heavy rainfall, the rush of water through the Blenheim-Gilboa Pumped Storage Power Project 40 miles (64 km) upstream hit a historic high. To cope with the overload, the dam released water into the Scholarie Creek according to the rate at which it was entering the reservoir from upstream.[5]

Thornton-Tomasetti, P. C. (1987) “Overview Report Investigation of the New York State Thruway Schoharie Creek Bridge Collapse.” Prepared for: New York State Disaster Preparedness Commission, December 1987.